stringent constraint on galactic positron production the ohio state university Phys. Rev. Lett. 97, 071102 (2006) [astro-ph/0512411] in collaboration with john beacom Workshop on TeV Particle Astrophysics 28-31 August 2006 Madison, WI, USA
views of the galaxy in low energy gamma rays 0.511 MeV annihilation line map by INTEGRAL Knodlseder et al [astro-ph/050626] 1050 positrons are annihilated per year producing 0.511 MeV line flux of about 10-3 photons cm -2 s -1 1-3 MeV diffuse gamma ray map by COMPTEL Strong et al [astro-ph/9811211] h a s a n yü k s el t h e o h i o s t a t e u n i v er s i t y s t r in g en t co n s t ra i n t o n g a l a c t ic p o s i t r o n p ro d u c t i o n T ev W o rk s h o p Ma di s o n W I 2 0 0 6 2
many models/studies on positron production astrophysical M. Casse, B. Cordier, J. Paul and S. Schanne, Hypernovae/GRB G. Bertone, A. Kusenko, S. Palomares-Ruiz, S. Pascoli and D. Semikoz, Gamma ray bursts P. A. Milne, J. D. Kurfess, R. L. Kinzer and M. D. Leising, SNe and Positron Annihilation N. Prantzos,.. intensity and spatial morphology of the 511 kev emission Agaronyan Atoyan 1981..Galactic positrons...among many others... exotic C. Picciotto and M. Pospelov, Unstable relics D. H. Oaknin and A. R. Zhitnitsky, Color superconducting dark matter D. Hooper and L. T. Wang, Axino dark matter in the galactic bulge P. H. Frampton and T. W. Kephart, Primordial black holes F. Ferrer and T. Vachaspati, Superconducting cosmic strings S. Kasuya and F. Takahashi, Q balls M. Kawasaki and T. Yanagida, Moduli decay...among many others... MeV dark matter C. Boehm, D. Hooper, J. Silk, M. Casse, and J. Paul, MeV dark matter [1-100 MeV] P. D. Serpico and G. G. Raffelt, MeV-mass dark matter and primordial nucleosynthesis J. F. Beacom, N. F. Bell and G. Bertone, Gamma-ray constraint on 511 S. Ando E. Komatsu & K. Ahn and E. Komatsu, MeV Dark matter...among many others... models yielding energies from few MeVs up to GeVs 3
0.511 MeV line and positronium formation Φ = (1.07 ± 0.03) x 10-3 cm-2 s-1 0.511 f: fraction of positrons forming positronium for each annihilated positron: 2 (1 ¾ f) 2γ line 3 ( ¾ f) 3γ continuum their ratio suggests: f = 0.967 ± 0.022 Jean et al [astro-ph/0509298] 4
interstellar medium at the GC and energy loss direct astromical probes suggests: very weak ionized component (~10 %) Moskalenko, Strong, Ormes, Potgieter 2002 line width suggests either: a single-phase weakly-ionized warm medium Churazov et al [astro-ph/0411351] a multi-phase medium dominated by warm neutral and warm ionized phases Jean et al [astro ph/0509298] positrons injected with energies 1-10 MeV may traverse distances of several Mpcs but can not diffuse more than few pcs from their origins due to magnetic fields of µg (typical of the region) 5
inflight annihilations and positron survival 66 as noted by Heitler in Quantum Theory of Radiation (1954): up to 20% of ultrarelativistic positrons may annihilate inflight 1.4 %, 5.5 %, 11% of positrons injected with energies 1, 3, 10 MeV are annihilated in flight until they lose most of their energy 6
gamma ray spectrum from inflight annihilations the differential cross section is sharply peaked at the endpoints of the k range as injected positrons lose energy, the low-energy peak remains below 0.511 MeV, where gamma rays are accumulated, while the high-energy peak moves slowly down to 0.511 MeV, producing a long tail Stecker 1969, Svensson 1982, Aharonian Atoyan Sunyaev 1982 7
inflight annihilation spectra normalized to 0.511 line flux Beacom & Yüksel [astro-ph/0512411] inflight annihilation gamma ray spectrum Beacom & Yüksel internal bremsstrahlung gamma ray spectrum Beacom Bell Bertone, 2005 for positrons injected with 1, 3, 10 MeV 8
geometry of positron annihilation region the morphology of the angular distribution is well fit by a two-dimensional Gaussian of ~8 at FWHM then the peak flux is ~0.048 photons cm 2 s 1 sr 1 with 24% (80%) of the photons coming from a cone of half-angle ~2.5 (~6 ) and the corresponding average fluxes are 0.042 (0.025) photons cm 2 s 1 sr 1 Knodlseder et al [astro-ph/050626] 9
diffuse gamma ray flux at the galactic center COMPTEL measurements of the diffuse flux in the galactic disk region, 330<l<30 and b <5 (Strong et al [astro-ph/9811211] ) can be approximated as: also agrees with the diffuse flux below 1 MeV from INTEGRAL Strong et al [0509290] 10
diffuse flux vs. excess from inflight annihilations about 24 % of 0.511 MeV positrons are coming from a cone of halfangle ~2.5 at the galactic center Beacom & Yüksel [astro-ph/0512411] diffuse + IA + IB diffuse + IA for positrons injected with energies over 3 MeV, the excess radiation from inflight annihilations would exceed the diffuse gamma-ray flux in the same region diffuse no such excess is seen in the COMPTEL sky maps for 1 3 MeV and 3 10 MeV energy bins see also Sizun Casse Schanne 2006 11
summary and conclusions the intense 0.511 Mev gamma-ray line emission from the galactic center observed by integral requires a large annihilation rate of nonrelativistic positrons if these positrons are injected at even mildly relativistic energies, higher-energy gamma rays will also be produced we calculate the gamma-ray spectra due to inflight annihilations (and internal bremsstrahlung) and compare to the observed diffuse galactic gamma-ray data even in a simplified but conservative treatment, we find that the positron injection energy below 3 MeV is favored this bound is far below the energy scales suggested in some recent models and it is therefore clearly very constraining 12